Literature DB >> 27409528

Accelerated Biofluid Filling in Complex Microfluidic Networks by Vacuum-Pressure Accelerated Movement (V-PAM).

Zeta Tak For Yu1, Mei Ki Cheung1, Shirley Xiaosu Liu1, Jianping Fu1,2,3,4.   

Abstract

Rapid fluid transport and exchange are critical operations involved in many microfluidic applications. However, conventional mechanisms used for driving fluid transport in microfluidics, such as micropumping and high pressure, can be inaccurate and difficult for implementation for integrated microfluidics containing control components and closed compartments. Here, a technology has been developed termed Vacuum-Pressure Accelerated Movement (V-PAM) capable of significantly enhancing biofluid transport in complex microfluidic environments containing dead-end channels and closed chambers. Operation of the V-PAM entails a pressurized fluid loading into microfluidic channels where gas confined inside can rapidly be dissipated through permeation through a thin, gas-permeable membrane sandwiched between microfluidic channels and a network of vacuum channels. Effects of different structural and operational parameters of the V-PAM for promoting fluid filling in microfluidic environments have been studied systematically. This work further demonstrates the applicability of V-PAM for rapid filling of temperature-sensitive hydrogels and unprocessed whole blood into complex irregular microfluidic networks such as microfluidic leaf venation patterns and blood circulatory systems. Together, the V-PAM technology provides a promising generic microfluidic tool for advanced fluid control and transport in integrated microfluidics for different microfluidic diagnosis, organs-on-chips, and biomimetic studies.
© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Entities:  

Keywords:  blood; gels; liquid filling; microfluidics; vacuum

Mesh:

Substances:

Year:  2016        PMID: 27409528      PMCID: PMC6215695          DOI: 10.1002/smll.201601231

Source DB:  PubMed          Journal:  Small        ISSN: 1613-6810            Impact factor:   13.281


  29 in total

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5.  Integrated microfluidic devices for combinatorial cell-based assays.

Authors:  Zeta Tak For Yu; Ken-ichiro Kamei; Hiroko Takahashi; Chengyi Jenny Shu; Xiaopu Wang; George Wenfu He; Robert Silverman; Caius G Radu; Owen N Witte; Ki-Bum Lee; Hsian-Rong Tseng
Journal:  Biomed Microdevices       Date:  2009-06       Impact factor: 2.838

Review 6.  Microfluidic blood cell sorting: now and beyond.

Authors:  Zeta Tak For Yu; Koh Meng Aw Yong; Jianping Fu
Journal:  Small       Date:  2014-02-10       Impact factor: 13.281

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Authors:  Yan Gao; Peng Li; Dimitri Pappas
Journal:  Biomed Microdevices       Date:  2013-12       Impact factor: 2.838

8.  Generation of a chemical gradient across an array of 256 cell cultures in a single chip.

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Review 10.  Extracellular matrix: a dynamic microenvironment for stem cell niche.

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  4 in total

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2.  A microfluidics-based stem cell model of early post-implantation human development.

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3.  Hydrophilic Sponges for Leaf-Inspired Continuous Pumping of Liquids.

Authors:  Tingjiao Zhou; Jinbin Yang; Deyong Zhu; Jieyao Zheng; Stephan Handschuh-Wang; Xiaohu Zhou; Junmin Zhang; Yizhen Liu; Zhou Liu; Chuanxin He; Xuechang Zhou
Journal:  Adv Sci (Weinh)       Date:  2017-04-19       Impact factor: 16.806

4.  An easy-to-build and re-usable microfluidic system for live-cell imaging.

Authors:  Julien Babic; Laurent Griscom; Jeremy Cramer; Damien Coudreuse
Journal:  BMC Cell Biol       Date:  2018-06-20       Impact factor: 4.241
  4 in total

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